Anna S. Weiss (Dübendorf / DE), Lisa Niedermeier (München / DE), Alexandra von Strempel (München / DE), Anna G. Burrichter (München / DE), Chen Meng (Freising / DE), Karin Kleigrewe (Freising / DE), Chiara Lincetto (München / DE), Johannes Hübner (München / DE), Barbara Stecher (München / DE)
Microbe-microbe interactions are critical for gut microbiome function. A challenging task to understand health and disease-related microbiome signatures is to move beyond descriptive community-level profiling towards disentangling microbial interaction networks. Using a synthetic gut bacterial community (OMM12), we aimed to study the role of individual members in community assembly, identify putative keystone species and test their influence across different environments. Single-species dropout experiments revealed that bacterial strain relationships strongly vary not only in different regions of the murine gut, but also across several standard culture media. Mechanisms involved in environment-dependent keystone functions in vitro included exclusive access to polysaccharides as well as bacteriocin production. Further, Bacteroides caecimuris and Blautia coccoides were found to play keystone roles in gnotobiotic mice by impacting community composition, the metabolic landscape and inflammatory responses. In summary, this work highlights the strong interdependency between bacterial community ecology and the biotic and abiotic environment. Our results question the concept of universal keystone species in the gastrointestinal ecosystem and underline the context-dependency of both, keystone functions and bacterial interaction networks.